![Solutions and Explanations
1. a) The speed of the wave v is given by the formula:
v = λ*f
λ of a standing wave is given by 2L/m where m is an integer > 1 and is equal to the number of
antinodes between the fixed ends of the string.
v = (2L/m)*f where L= length of the string=0.300m and m=1 because this is the fundamental
frequency and there is only one antinode.
v = (2*0.300m)*(440Hz) = 264 m/s
b) The frequency of a standing wave is given by the formula:
f = [(m/(2L)]*sqrt(T/µ)
m=1
f*(2L)=sqrt(T/µ)
(2f*L)2=T/µ
(2f*L)2µ = T
T = (2*440Hz*0.45m)2/(0.000652 kg/m)
T = 102 N
2. a)
f = [m/(2L)]*sqrt(T/µ)
f=[m/(2L)]*v
we know the wave speed v from the previous question, and m=2 this time because this is the
second harmonic (2 antinodes)
f = (1/0.300m)(264 m/s)
f = 880 Hz
b) The same process is applied as in part a), where m=3 because it is the third harmonic. We end
up with f=1320
Notice that
f=(m/2L)*v
f=m(1/2L)*v and (1/2L)*v is the fundamental frequency of a string, so by increasing m or
increasing the harmonics,
fm=m*f1
where fm is the frequency of the mth harmonic and f1 is the fundamental frequency.](data:image/gif;base64,R0lGODlhAQABAIAAAAAAAP///yH5BAEAAAAALAAAAAABAAEAAAIBRAA7)
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Lo 6
- 1. Learning Object 6: Standing Waves and Music An example of standing waves on the strings of a violin is used to illustrate how the formulas presented for standing waves on a string are applied. *N=nodes in this diagram 1. A tuned string on a violin is 30.0 cm long, and vibrates with a fundamental frequency of 440 Hz (the A4 note). The string has a linear mass density of 0.652 g/m. a) What is the wave speed? b) What tension must another 45.0 cm string with the same linear mass density as the violin string have to have in order to vibrate at 440 Hz? (assume the length of the string does not change while increasing the tension) 2. For people who have played strings instruments before, we know that when we gently press our finger at certain positions on the string, harmonic notes are played. What are the frequencies that are produced when the original violin string is played at its a) second harmonic? b) third harmonic?
- 2. Solutions and Explanations 1. a) The speed of the wave v is given by the formula: v = λ*f λ of a standing wave is given by 2L/m where m is an integer > 1 and is equal to the number of antinodes between the fixed ends of the string. v = (2L/m)*f where L= length of the string=0.300m and m=1 because this is the fundamental frequency and there is only one antinode. v = (2*0.300m)*(440Hz) = 264 m/s b) The frequency of a standing wave is given by the formula: f = [(m/(2L)]*sqrt(T/µ) m=1 f*(2L)=sqrt(T/µ) (2f*L)2=T/µ (2f*L)2µ = T T = (2*440Hz*0.45m)2/(0.000652 kg/m) T = 102 N 2. a) f = [m/(2L)]*sqrt(T/µ) f=[m/(2L)]*v we know the wave speed v from the previous question, and m=2 this time because this is the second harmonic (2 antinodes) f = (1/0.300m)(264 m/s) f = 880 Hz b) The same process is applied as in part a), where m=3 because it is the third harmonic. We end up with f=1320 Notice that f=(m/2L)*v f=m(1/2L)*v and (1/2L)*v is the fundamental frequency of a string, so by increasing m or increasing the harmonics, fm=m*f1 where fm is the frequency of the mth harmonic and f1 is the fundamental frequency.